25 May - 5 Jun 2025
Sharm El-Sheikh (Egypt)
Hotel : Sheraton Sharm Hotel
Cost : 6720 € Euro
Welcome to the Power System Transmission and Control training program the Global Horizon Training Center offers. This comprehensive program is designed to provide participants with a deep understanding of power system transmission principles, control strategies, and technologies. Whether you are a professional in the energy sector or a student aiming to enhance your knowledge, this program will equip you with the necessary skills to navigate the complexities of power transmission and control.
By the end of this training program, participants will be able to:
Understand the fundamentals of power system transmission and distribution.
Explain the importance of efficient power transmission in modern energy networks.
Analyze different types of power system controls and their applications.
Evaluate the challenges and solutions in maintaining grid stability and reliability.
Apply advanced technologies in power system monitoring, protection, and control.
The training program will employ a balanced approach of theoretical learning, practical case studies, group discussions, and hands-on exercises. Participants will have access to industry-standard simulation tools and software to gain practical experience in power system control scenarios.
Engineers and technicians working in the energy and power sectors.
Electrical and power engineering students and graduates.
Professionals seeking to expand their knowledge in power system control.
Anyone interested in understanding the intricacies of power transmission and control systems.
Day 1:
Introduction to Power System Transmission
Basics of electricity and power systems.
Components of a power system: generation, transmission, distribution.
Importance of efficient power transmission.
Role of power grids in modern society.
Day 2:
Power Grid Structure and Components
Overview of power grid hierarchy: generation, transmission, distribution.
Substations, transformers, circuit breakers, and other key components.
Transmission line types: overhead, underground, submarine.
Challenges and considerations in designing power transmission systems.
Day 3:
Power System Stability and Control
Understanding power system stability and its significance.
Factors affecting stability: load variations, faults, disturbances.
Voltage control: importance, methods, and devices.
Frequency control: primary and secondary control, load shedding.
Day 4:
Generator Control and Excitation
Role of generators in power generation.
Generator excitation and its impact on system stability.
Automatic Voltage Regulators (AVRs) and excitation control systems.
Synchronous generators and their control characteristics.
Day 5:
Grid Monitoring Technologies
Importance of real-time grid monitoring.
SCADA (Supervisory Control and Data Acquisition) systems.
Phasor Measurement Units (PMUs) and synchrophasors.
Data analytics for grid monitoring and maintenance.
Day 6:
Power System Protection and Relaying
Basics of power system protection.
Types of faults: short-circuit, overcurrent, underfrequency.
Protective relays and their operation.
Coordination of protection devices for system reliability.
Day 7:
Introduction to FACTS
Flexible AC Transmission Systems (FACTS) and their role.
Voltage and phase angle control using FACTS devices.
Types of FACTS devices: SVC, STATCOM, UPFC.
Benefits of FACTS in enhancing grid stability.
Day 8:
HVDC Transmission Control
Advantages of High Voltage Direct Current (HVDC) transmission.
Control strategies in HVDC systems.
Inverter and rectifier control in HVDC converters.
HVDC applications in long-distance transmission and interconnecting grids.
Day 9:
Smart Grid Technologies
Concept and significance of smart grids.
Smart grid components: smart meters, communication networks.
Demand response and load management.
Integration of renewable energy sources in smart grids.
Day 10:
Practical Applications and Future Trends
Hands-on simulation exercises using industry software (e.g., PSCAD, MATLAB).
Case studies of real-world power system control scenarios.
Control challenges and opportunities with the integration of renewables.
Emerging trends in power transmission and control technologies.